Journal of Physical and Chemical Reference Data 13, 601 (1984); https://doi.org/10.1063/1.555714 13, 601
© 1984 American Institute of Physics for the National Institute of Standards and Technology.
Thermophysical Properties of Fluid D2O
Cite as: Journal of Physical and Chemical Reference Data 13, 601 (1984); https://doi.org/10.1063/1.555714Published Online: 15 October 2009
J. Kestin, J. V. Sengers, B. Kamgar-Parsi, and J. M. H. Levelt Sengers
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Thermophysical Properties of Fluid 0 20
J. Kestin
Division 0/ Engineen'ng, Brown University, Providence, Rhode Island 02912 and Thermophysics Division, National Bureau of Standards, Gaithersburg, Maryland 20899
J. V. Sengers
Thermophysics Division, National Bureau of Standards, Gaithersburg, Maryland 20899 and Institutefor Physical Science and Technology, University of Maryland, College Park. Maryland 20742
B. Kamgar-Parsi
Institute/or Physical Science and Technology, University of Maryland, College Park, Maryland 20742
and
J. M. H. Levett Sengers
Thermophysics Division, National Bureau of Standards, Gaithersburg, Maryland 20899
The present publication contains data on the thermophysical properties of deuterium oxide (heavy water), It is a companion to the paper on the thermophysical properties of fluid H 20 published earlier in this journal by the same authors. The properties are represented by equations which can be readily programed on a computer and incorporated in data banks. All data have been carefully and critically analyzed. The compendium repre-sents the best available data for fluid D20. .
Key words: critical parameters; equation of state; fundamental equation; heavy steam; heavy water; thermal conductivity; thermodynamic properties; viscosity,
Contents
1. Introduction.... .................... ........ ................ ....... 601 2. Molecular Data ............... ;.................................. 603 3. Critical Constants .......... .......... .......................... 603 4. Triple Point.... .......... .......... .................... ............ 603 S. Dimensionless Variables and Reference Con-
stants .................................................................. 603 6. Equilibrium Thermodynamic -Properties in the
Analytic Range ......... ......... ................................ 604 7. Ideal-Gas Properties ............ ...... ................ ........ 606 8. Equilibrium Thermodynamic Properties in the
Critical Region...................... .............. ............... 606 9. Vis.cos.ity.. ..... ...... ........ ............. ....... ...... .............. 607
10. Thennal Conductivity........................................ 608 11. Computer-Program Verification ........................ 608 12. Acknowledgments .............................................. 608
1. Introduction The present publication contains data on the thermo
physical properties of deuterium oxide alias heavy water
® 1984 by the::: U, S. Se:::CICti:UY UfCUUIlIlClt,;e::: 011 bdudf of the UuiLeu St<tlc::::s,
This copyright is assigned to the American Institute of Physics and the American Chemical Society. Reprints available from ACS; see Reprint List at back of issue.
0047-2689/84/020601-09/$05.00
13. References .......................................................... 609
List of Tables
1. Coefficients A OJ .................................................... 60S 2. Coefficients A ij ........ ........ ........... ....... ..... ...... ........ 605 3. Parameters 1'j and,oi ........................................... 605 4. Coefficients for fundamental equation in the criti~
cal region .......... ............. ....... ......... ..... ........... ....... 607 S. Coefficients for polynomials p;(f}) ........................ 607 6. Coefficients Hi . ..................... ....... ..... ......... ........... 607 7. Coefficients H ij .... ........... ...... ........... ............ ......... 607 8. Coefficients for 1 (1', ,0) ....................... .................. 608 9. Thermophysical property values calculated for
601
selected values of l' and ,0 ................... ~................. 608
(D20). It is a companion to the paper on the thermophysical properties of fluid H 20 published earlier in this journal by the same authors. 1 The properties are represented by equations which can be readily programed on a computer and incorporated in data banks. Most of the numerical values and formulations have been studied quite extensively by the International Association for the Properties of Steam (lAPS) and several of the formulations have been endorsed as inter-
J. Phys. Chern. Ref. Data, Vol. 13, No.2, 1984
602 KESTIN ET AL.
national standards.2 It must, however, be emphasized that the present publication, like the preceding publication on the thermophysical properties of light water,1 is not issued under the authority of lAPS. The aim is to supply the best contemporary values for the thermophysical properties of fluid D20 as judged by the present authors regardless of international agreements.
Heavy water is of interest in a number of applications in engineering and physics. In engineering, heavy water is used for its excellent nuclear and thermal properties. These make it suitable as a moderator in nuclear reactors because D20 possesses a small cross section for the capture of neutrons. Since the thermal properties of heavy water are very much like those of light water, it is very suitable for use both as a moderator in homogeneous reactors using natural uranium and as a working fluid in nuclear reactors for power applications (CANDU-Canadian deuterium reactor for the production of electricity). For example, heavy water freezes at 3.8 °C under a pressure of 1 atm and its normal boiling point is 101.42°C; the maximum density of the saturated liquid occurs at 11.2°C. At 20°C, its density is 1.1050 kg/dm3
compared to 0.9982 kg/dm3 for H20. In view of the applications of heavy water, many re
search workers have measured the thermodynamic and transport properties of heavy water and prepared computer codes for their representation.3 The material thus generated is of sufficient reliability to justify the present publication.
From the point of view of a physicist, the two versions of water, H20 and D20, whose properties are probably better known than for any other isotopic pair of fluids. constitute a valuable system for the study of the relationships between isotopes.
The discovery of the heavy isotope D of hydrogen, whose atomic mass is double that of the latter, was made in 1931 by H. C. Vrey, G. M. Murphy, and F. G. Brickwedde.4
•5 The leader of theteam, Harold Vrey, was awarded
the Nobel Prize for this discovery in 1934. It is interesting to note that, not unlike the case of the discovery of argon by Lord Rayleigh6 (for which he was also honored with the Nobel Prize), the possibility of the existence of an isotopic version of water was foreshadowed by the very accurate measurements of the density of pure water performed by A. B. Lamb and R. E. Lee in 1913.7 Their measurements of various samples of water,5 carefully prepared and purified, varied in density by as much as (or as little as!) 8 X 10-7 gI cm3
, in the face of a precision of measurement of2 X 10-7 g/ ClU
3• This difference was later quoted as evidence of the exis
tence of an isotope. Heavy hydrogen gives rise to two isotopes of water,
namely HDO with a molar mass of 19 glmol and D20 with a molar mass of 20 g/mol, against 18 g/mol for H20. The first sample of practically pure D20 was produced in 1933 by G. N. Lewis and R. T. MacDonald.8 This marked the beginning of the research into its thermophysical properties.
It is remarkable that the isotopic composition of naturally occurring water on earth varies very little from place to place. In order to secure very accurate reproducibility, H. Craig created a standard known as Standard Mean Ocean Water (SMOW).9-11 Since oxygen possesses three stable iso-
J. Phys. Chem. Ref. Data, Vol. 13, No.2, 1984
topes, 160,170,180; the composition specification for SMOW is quite complex, as shown hereunder:
Component IH 2H(D) 3H(T)
160 170 180
Mole fraction 0.999842 0.000 158 o 0.997640 0.000371 0.001989
In the present paper, it is assumed that heavy water consists of 100% D20 with the same relative abundance of oxygen isotopes as in SMOW.
A survey of various thermophysical and chemical properties of heavy water was published In 1951 in the U.S. in a book by Kirshenbaum. 12 Subsequently, a comprehensive collection of thermo physical property information, including tables of thermodynamic properties of heavy water, was published by V. A. Kirillin and co-workers in the Soviet Union. 13 At the time, the authors could claim that they had taken into account "all experimental and theoretical data published in their country and abroad," even though the work was done without the availability of computers.
A global fundamental equation, and new tables of thermodynamic properties of heavy water derived from it, were recently published by P. G. Hill, R. D. C. MacMillan, and V. Lee of the University of British Columbia in Canada. 14.15
This fundamental equation has been adopted by lAPS as the Provisional lAPS Formulation 1983 for the Thermodynamic Properties of Heavy Water Substance. 2 The global fundamental equation quoted in this paper is a dimensionless version of the fundamental equation of Hill et aZ.
Present-day understanding of the thermodynamic properties of any substance, including D20, indicates that the thermodynamic surface becomes nonanalytic at thecritical point. Thus it is convenient to exclude a small near-criti· cal region from the thermodynamic surface specified by the analytic global fundamental equation mentioned above. Inside this critical region, recourse is made to the scaling laws predicted by theory for the critical behavior of substances. 16
The question may be raised whether the properties of heavy water could not have been simply predicted from those oflight water with the aid of the law of corresponding states. The answer is that, although this law seems to hold well for several of the properties of these two substances, there are notable exceptions. Properties that do show corre~ spondencc are the· critical compressibility factor
Zc = Pc Vc / R Tc and the compressibility factors in the vapor and liquid phases from 20 to 300 °C. The differences of a few tenths of a percent noted by Hill and Lee17 are within the uncertainty of the critical parameters used as reduction factors. The anomalous (scaled) parts of the critical properties of the two substances are identical within the accuracy ofthe data when expressed in reduced units. 16 On the other hand, significant departures from corresponding states have been found for the vapor-pressure curves. Although the critical temperature of heavy water is 3.2 K lower than that oflight water, its triple point temperature is 3.8 K higher. The reduced slopes of the vapor pressure curves differ by 0.5% at
THERMOPHYSICAL PROPERTIES OF FLUID 020 603
the critical point. At reduced temperatures from 0.85 down to 0.6, the reduced vapor pressure of D 20 is a few percents lower than that of H 20. At lower temperatures, the differences become larger; near the triple point the reduced vapor pressure of D 20 is approximately 30% below that of H 20.
Thus, although the assumption of corresponding states for D 20 and H 20 is quite sensible, the departures definitely exceed the accuracy of the data for some of the properties. Hence, an accurate thermodynamic surface cannot be obtained on the basis of this assumption.
Equations for the transport properties of fluid D 20 have been developed by N. Matsunaga and A. Nagashima of Keio University in Yokohama. 18 These equations have been adopted by lAPS as the international representation of the transport properties of heavy water substance2 and we have incorporated these equations in this paper.
All equations have been programed on computers and I
calculated results were checked against critically evaluated experimental data. A short numerical table is included in this paper solely for the purpose of verifying computer codes.
The authors hope that this selection of formulas will be of use to all those who need computer codes for the thermophysical properties of fluid D 20.
2. Molecular Data
universal gas constane9:
specific gas constant:
M = 0.020027478 kglmol,(2.1)
R = 8.31441 Jlmol K, (2.2)
r = 415.150 J/kg K. (2.3)
The molar mass refers to 100% D 20 with the same relative abundance of oxygen isotopes as in standard mean ocean water. II
3. Critical Constants
Critical temperature: Ter
critical pressure: Per
= (643.89 + 8)K = (370.74 + ~ rC with - 0.2<8< + 0.2, = (21.671 + 0.278 ± 0.010)MPa,
(3.1)
(3.2)
(3.3)
(3.4)
critical density: Per = (356 ± 5)kg/m3,
critical specific volume: Vcr = (0.002 81 ± 0.000 04)m3/kg,
as adopted by the International Association for the Properties of Steam.2
The above values for the critical constants are the results of measurements which may be repeated and improved. On the other hand, critical parameters are often used as reference quantities in correlations. Once adopted, such refer-
I
ence constants need not be revised when our knowledge of the critical constants improves. In order to distinguish the reference constants from the critical constants (to which they are close), we denote the reference constants by asterisks: P *, T *, P* and treat them as empirical correlation constants throughout the remainder of the publication.
4. Triple Poinf4,2o.21
Triple-point temperature:
triple-point pressure:
density of liquid at
T tr = (276.97 ± 0.02)K = (3.82 ± 0.02tC, Ptr = (661 ± 3) Pa,
(4.1)
(4.2)
triple point: Ptr,L = (1105.5 ± O.2)kglm3, (4.3)
density of vapor at triple point: Ptr,G = (0.005 75 ± 0.000 03)kg/m3. (4.4)
5. Dimensionless Variables and Reference Constants
All equations in this publicatiuIl an:: pn~sentt:d in nondimensional form. The dimensionless version of each quantity
I
I is denoted by a symbol with a bar. The reference quantities consist of two classes: five primary reference quantities (denoted by an asterisk) and three secondary reference quantities (denoted by a double asterisk) which are simple combinations of the primary reference quantities.
5.1. Primary Reference Constants
Reference temperature:
reference density:
reference pressure:
reference viscosity:
T* = 643.89 K,
p* = 358kglm3,
p* = 21.671 X 106 Pa,
"1* = 55.2651 X 10-6 Pa s,
(5.1)
(5.2)
(5.3)
(5.4)
J. Phys. Chem. Ref. Data, Vol. 13, No.2, 1984
604 KESTIN ET AL.
reference thermal conductivity: A * = 0.742 128X 10-3 W /K m. (5.5)
It is emphasized that the three reference constants T *, p* ,P * are close to but not identical with the critical parameters Tcr,Pcr, P<;r:-
5.2 Secondary Reference Constants
Reference constant for Helmholtz function, energy, enthalpy, Gibbs function: A **== P * = 60 533.52 J/kg,
p* (5.6)
reference constant for entropy, specific heats: S **== ~ = 94.012 21 J/kg K,
p*T* (5.7)
reference constant for sound velocity: W**-- (Pp**)l!2 = 246.036 m/s. (5.8)
5.3. Thermophysical Properties in Dimensionless Form
Temperature: T = T/T*, (5.9) pressure: P =P/P*, (5.10) density: e.. =p/p*, (5.11) specific volume: V = Vp*, (5.12) specific Helmholtz function: 1 =A/A **, (5.13) specific energy: Ii = U/A **, (5.14) specific enthalpy: H =H /A **, (5.15) specific Gibbs function: G = G/A **, (5.16) -chemical potential: J-t =J-t/A **, (5.17) specific entropy: S =S/S**, (5.18) specific heat at constant Cv = Cv/S**, (5.19) volume: specific heat at constant Cp = Cp/S**, (5.20) pressure: isothermal compressibility: KT =KTP*, (5.21) symmetrized compressibility: X T =XTP*/p*2, (5.22) speed of sound: W = w/w**, (5.23) viscosity: 1j = 17/17*, (5.24) thermal conductivity: X =..1./..1.*. (5.25)
6. Equilibrium Thermodynamic Properties in the Analytic Range
All equilibrium thermodynamic properties in the analytic region, that is, to the exclusion of a small area near the critical point, are implied by the canonical equation
A=A(T,p), (6.1)
in which the Helmholtz free energy A is represented as a function of temperature and density.
The equation is based on the formulation constructed by Hill, MacMillan, and Lee.14
,15 It has been provisionally adopted by the International Association for the Properties of Steam as the Provisional lAPS Formulation 1983 for the Thermodynamic Properties of Heavy Water Substance.2 For the present publication the original equation 15 has been converted to a non dimensional form for convenience of programing. In order to change the system of units in the output, it is sufficient to perform the conversion in the primary
J. Phys. Chern. Ref. Data, Vol. 13, NO.2, 1984
and secondary reference constants given earlier in Secs. 5.1 and 5.2.
6.1. Fundamental Equation in Canonical Form
(6.2)
with 7
AiT,p) = (Aoo + AOIT)ln T + L Ao/f J -2 + AogTlnp,
j=2
--_ -_(1 1) 7 (1 l)i-2 A 1(T,p) = Tp -= - -=- I-=-- =-
T Tl i=1 T T;
[
g 10] X L Aij{p - p;)i- 1 + e-1.5394p L Aij pj-9 •
j=1 j=9
The fundamental Eq. (6.2) covers the range
P<;l00MPa, T tr <;T<;800K.
(6.3)
(6.4)
(6.5)
We recommend the analytic fundamental equation everywhere in this range except for a region around the critical point bounded by
0.991<1\;;1.06, 0.7<,0<1.3. (6.6)
Inside the range bounded by Eq. (6.6), a more accurate representation of the derivatives of the thermodynamic surface is obtained from the nonanalytic equation presented in Sec. 8.
6.2. Parameter Values for Fundamental Equation
ThevaluesoftheparametersAij1 1';, andpi in theequations for 10 and Al are given in Tables 1-3. In all tables presented in this paper, we have adopted the "E-notation." That is, the integer which follows E indicates the power of ten by which the listed coefficient value should be multiplied.Thus E + 2 represents the factor 102 = 100, etc.
The choice of the coefficientsA02 andAo3 in Eq. (6.3) is related to the convention adopted for the zero points of energy and entropy. Unlike the case of H20, the choice of the reference point for internal energy and entropy presents us with a problem. In the case of H20, the values of specific
THERMOPHYSICAL PROPERTIES OF FLUID 0 20 605
j
o 1 2 3 4 5 6 7 8
2 2 2 2 2 2 2 2 2 2 3 3 3 3 3 3 4 4 4 4 4 4 5 5 5 5 5 5 6 6 6 6 6 6 7 7 7 7 7 7
j
2 3 4 5 6 7
8 9
10 1 2 3 4 5 6 7 8 9
10 1 2 3 4 9
10 1 2 3 4 9
10 1 2 3 4 9
10 1 2 3 4 9
10 1 2 3 4 9
10
TABLE 1. Coefficients A OJ
0.5399322597E - 2 - 0.1288399716E + 2
0.3087284587£ + 2 - 0.3827563059E + 2
0.4424799189E + 0 - 0.1256336874E + 1
0.2843343470E + 0 - 0.2401555088E - 1
0.441:H~M023E +- 1
TABLE 2. CoefficientsAij
Aij
0.115623643567E + 3 - 0.16141339295lE + 3
0.108543003981E + 3 - 0.471342021238E + 2
0.149218685173E + 2 - 0.360628259650E + 1
0.6&67430264SSE + 0
- 0.95191372140lE - 1 - 0.157513472656E + 4 - 0.433677787466E + 3
0.607446060304E + 2 - 0.927952190464E + 2
0.632086750422E + 2 - 0.264943219184E + 2
0.905675051855E + 1 - 0.578949OO5123E + 0
0.66559044762lE + 0 - 0.525687146109E - 1 - 0.341048601697E + 4 - 0.146971631028E + 4
0.444139703648E + 2 - 0.580410482641E + 2
0.354090438940E + 2 - 0.144432210128£ + 2 - 0.102135518748E + 4 - 0.136324396122E + 4
0.157859762687E + 2 - 0.194973173813E + 2
0.114841391216E + 2 - 0.19695610301OE + 1 - 0.277379051954E + 3 - 0.481991835255E + 3 - 0.619344658242E + 2
0.791406411518E + 2 - 0.484238027539E + 2
0.191546335463E + 2 0.128039793871E + 4 0.186367898973E + 4
- 0.749615505949E + 2 0.947388734799E + 2
- 0.575266970986E + 2 0.173229892427E + 2 0.137572687525E + 4 0.231749018693E + 4
- 0.260841561347£ + 2 0.328640711440E + 2
- 0.186464444026E + 2 0.484262639275E + 1 0.430179479063E + 3 0.822507844138E + 3
Note: Coefficients Aij omitted from table are zero identically.
2 3 4 5 6 7
TABLE 3. Parameters T; andp;
0.1000038832E + 1 0.6138578282E + 0 0.6138578282E + 0 0.6138578282E + 0 0.6138578282E + 0 0.6138578282E + 0 0.6138578282E + 0
0.1955307263E + 1 0.3072625698E + 1 0.3072625698E + 1 0.3072625698E + 1 0.3072625698E + 1 0.3072625698E + 1 0.3072625698E + 1
energy and entropy of the liquid at the triple point are set equal to zero.l The temperature of the triple point of H20 need not be measured, because it constitutes the (single) fixed point on the internationally accepted Thermodynamic Scale and is, naturally, incorporated in the International Practical Temperature Scale. In the case ofD20, the triple-point temperature must be obtained from accurate measurements which are subject to improvement. Following Hill et al.,15 we have adopted as the reference point the liquid state at T t = 3.80 °C and at P t = 660.066 Pa which is the vaporliquid saturation pressure at 3.80 °C implied by the surface. Hen~e, at this pseudo-triple point we have
Tt = 276.95 K, Pt = 660.066 Pa,
Ut,L = 0, St,L = 0,
Ht,L = 0.597 J/kg.
(6.7)
(6.8)
(6.9)
Comparing Eq. (6.7) with Eqs. (4.1) and (4.2), we note that this pseudo-triple point may differ slightly from the "true" triple point and, in fact, it may correspond to a metastable liquid state. We do not think that this specific choice of the absolute values of U and S is important for most users for whom this paper is intended.
In the liquid region, small changes in density along an isotherm cause large changes in pressure. For this reason, due to an accumulation of small errors. a particular computer code may fail to return the zeros [Eq. (6.8)] at the liquid density which corresponds to the values of P t and T t imposed by Eq. (6.7). This problem can be solved by adjusting theconstantsAo2 andA03 in Eq. (6.3) so that condition (6.8) is satisfied with the desired accuracy.
6.3. Thermodynamic Relations
All thermodynamic properties of interest can be derived from the fundamental Eq. (6.2) by the use ofthe following thermodynamic relations
V=p-l, (6.10)
(6.11)
(6.12)
(6.13)
(6.14)
(6.15)
J. Phys. Chem. Ref. Data, Vol. 13, No.2, 1984
606 KESTIN ET AL.
7. Ideal-Gas Properties
(6.16)
(6.17)
(6.18)
(6.19)
(6.20)
(6.21)
(6.22)
The ideal-gas properties of D20 are obtained from
Aid = AiT,p) = (Aoo + AOIT)ln T 7
+ L Ao/f j-
2 +AosTlnp j=2
as a function of temperature and density, or from
as a function of temperature and pressure.
(7.1)
(7.2)
We remark that Hill and co-workers adopted the value r 415.147 J /kg K for the specific gas constant,22 rather than the recommended value r = 415.150 J/kg K given in Eq. (2.2). The dimensionless analytic equation given here is identical with the dimensional equation of Hill et al. 14 provided that one uses in the latter equation r = 415.147 J/kg K. The ilifference~, ohtainf"iI when the more accurate value r = 415. 150J/kg K is used, are unimportant.
8. Equilibrium Thermodynamic Properties in the Critical Region
In the critical region, Eq. (6.6), it is more convenient to represent the thermodynamic properties by means of a canonical equation among intensive variables. The form chosen here is16
(8.1)
8.1. Revised Dimensionless Variables for Critical Region
For a representation of the thermodynamic properties in the critical region, it is convenient to transform the reference temperature, density, and pressure to the value of these parameters at the critical point of the thermodynamic surface. Its coordinates now assume the role of revised reference constants and are defined by
Tc = 643.89 K or Tc Pc = 356.238 kg/m3 or 8: Pc =,21.6713 X 10" Pa or Pc
= 1.000 000, = 0.995 078, = 1.000014.
J. Phys. Chem. Ref. Data, Vol. 13, No.2, 1984
(8.2) (8.3) (S.4)
The canonical equation is so structured that its critical point is located at Tc'Pc' Pc.
The reduced variables employed in the canonical equation for the critical region are defined by
T Tc (8.5) if'
ji _ Ji PeTe (8.6) - T Pc '
P P 'Fe (8.7) = -=-.-=-, T Pc
jJ =p - , (8.8) Pc
U - 1 (8.9) =pU.-=-,
Pc
S -"8 Tc (8.10) =P '=-, Pc
A _ pA Te (8.11) - -=-.-=--,
T Pe
II _ pH Tc - T' Pc'
(S.12)
iT - P
(8.13) = TXT' - ~ 2' TcPc
Cv -c ifc (8.14) =P v'-=-,
Pc
Cp -c Tc (S.15) =P p'-=-,
Pc -crr w _ w Pc c (8.16) - -1/2 -=-- . T Pc
8.2. Fundamental Equation in the Critical Region
The canonical equation in the critical region is written in two parts, a regular part and a nonanalytic part which accounts for the critical anomalies. The former is expressed in terms of the natural variables Tandjl, defined in Eqs. (S.5) and (8.6). The latter part is parametrized with the aid of the following transformation.
Liji 11 - jiit) = r{3{ja8 (1 - ( 2),
LiT:=T+l=r(l b 2( 2 ) cr{3c5a8(1
(S.17a)
(2
), (S.17b)
where a, b, and c are constants. The variables rand () replace the original variables T and ji in the nonanalytic part in such a way that there are no singUlarities in the single-phase region except at the critical point itself.
The fundamental equation reads
l' = Preg + Psc '
with
Preg = 1'0(1') + Liji+ PuLijiLiT,
(8.1S)
(8.18a)
p sc = UkorP(8..j.. IlpO(fJ) + uk1r[P(8..j.. 1)..j.. A Jpl(O}. (s.18b)
The scaled part of the potential, Eq. (S.18b), is identical with that of light water. For this property, a law of corresponding states appears to hold very well. The functions llo(T) and
THERMOPHYSICAL PROPERTIES OF FLUID D20 607
TABLE 4. Coefficients for fundamental equation in the critical region
a = 23.667 ko= 1.4403 k} = 0.2942 c= 0.01776
b 2 = 1.3757 P} = 6.9107 Pz = -25.2370 1'3 = 8.6180 I'll = 0.547 64 lie = - 11.948 lit = - 24.219 liz = - 21.552 li3 = 17.308
TABLE 5. Coefficients for polynomialsp;(8)
Poo= P20 = - 1.026 243 P4<l = 0.612903 POI = 0.103 25 P21 0.160 32 P4t 0.16986
Po(1') are defined by _ _ 3 _ .
f.lo{T) = lie + L /tj(.aTY, j= 1
3
piT) = 1 + I Pj {.1 ry. j= 1
(8.19)
(8.20)
The functions Po( () ) and P 1 (() ) are polynomials of the form
p;(8) =POi +P2iB2 +P4i(} 4 (i=O,l). (8.21)
The critical exponents are
P = 0.325, 8 = 4.82,· .d = 0.50. (8.22)
The values of the other constants in Eqs. (8.17)-( 8.21) are listed.in Table 4. The coefficients POi of the polynomials Pi (8 ) defined in Eq. (8.21) are related to the critical exponents P,oA and the constant b 2 as discussed elsewhere16
; the numerical values of the coefficients Pm are given in Table 5. Note that the critical exponents P,oA, the constants a, ko, k1, C, b 2 and the polynomials po((}), Pl((}) are identical with those of light water. 1,23
8.3. Thermodynamic Relations
The various thermodynamic properties can be deduced from the fundamental Eq. (7.18) with the aid of the following
TABLE 6. Coefficients H j
Ho= 1.00000 Hi = 0.940 695 Hz = 0.578 377 H3 = - 0.202044
thermodynamic relations. 23
(8.23)
(8.24)
(8.25)
(8.26)
(8.27)
(8.28)
(8.29)
(8.30)
(8.31)
(8.32)
Note: Explicit expressions for the derivatives of the canonical equation can be found in Ref. 23.
9. Viscosity The viscosity is represented by the equationl8
(9.1)
The first term of the product gives the viscosity in the dilutegas limit and has the form
- (1')- IT 110 - 3 H.' L I
(9.2)
;=0
with the coefficients Hi given in Table 6. The second multi-
TABLE 7. coefficients Du
i= o
j=O 0.4864192 1 0.350900 7 2 - 0.284 757 2 3 0.070 137 59 4 0.01641220 5 - 0.011 638 15 6 0.0
- 0.244 837 2 1.315436
-1.037026 0.4660127
- 0.028 849 11 - 0.008 239 587
0.0
2
-0.8702035 1.297752
- 1.287846 0.2292075 0.0 0.0 0.0
3
0.8716056 1.353448 0.0
-0.4857462 0.160 7171 0.0
- 0.003 886 659
4
- 1.051 126 0.0 0.0 0.0 0.0 0.0 0.0
5
0.3458395 0.0
- 0.021482 29 0.0
- 0.009 603 846 0.004 559 914 0.0
J. Phys. Chem. Ref. Data, Vol. 13, No.2, 1984
608 KESTIN ET AL.
plicative factor is
1ilT,,o) = exp [,0 .f :± Hij (~ - 1); (,0 - l)jj, I=Oj=O T
(9.3)
with the coefticientsHij given in Table 7. Equation (9.1) for the viscosity covers the range
P<.I00 MPa, Ttr <.T<.775 K. (9.4)
The viscosity is expected to show a small enhancement in the immediate vicinity of the critical point as it does for H 20. 24
The effect is small and is neglected in Eq. (9.1).
10. Thermal Conductivity The thermal conductivity is represented by the equa
tion18
A = Ao(f') +Al(P) +XiT,p) +XiT,p). (10.1)
The first term liT) gives the thermal conductivity in the dilute-gas limit and has the form
5
loer) = I Lo/fi. (10.2) i=O
The other terms in Eq. (10.1) are defined by the equations 4
with
11(,0) = L lO [ 1 - exp( - 2.506,0)] + L Lli pi, (10.3) ;=1
lir,,o) = L 20/g
X[1 +~{ L21/4 1 + exp [ 60(7 - 1) + 20]
+ L22 g .} 1 (10 4) 1 + exp [ 1 OO( 7 - 1) + 15]' .
T 7= -=-----
IT-I.ll + 1.1'
lir,,o) = L30/6
/5
{ 1 - exp [ - (0.4,0) 10] } .
(10.4a)
(10.5)
The auxiliary functions / I(T) and g g(,o) are
/(1') = exp[T(fo + itT)], (10.6)
g(p)=exp[go(,o 1)2J +glexplg2(P-,oo)2]. (10.7)
The values of the coefficients in these equations are given in Table 8. Equation (10.1) for the thermal conductivity covers the range
P<.l00 MPa, Ttr <T<825 K. (10.8)
Loo= LOJ = L02 = L03 = L04= L05=
LIO=
Ll1 =
L 12 = L13= L 14 =
TABLE 8. Coefficients for X {T, p)
1.00000 37.3223 22.5485 13.0465 0.0
- 2.60735
-167.310
483.656
-191.039 73.0358
-7.57467
L 20 L21 L22 fo It go gl g2
Po
L30
0.354 296x lOS 0.5X1010
3.5 0.144 847
- 5.64493 - 2.80000 - 0.080 738 543
- 17.9430
0.125698
= -741.112
The thermal conductivity of any fluid, including D20, exhibits a critical enhancement in a large range of densities and temperat.ures around the critical point. This critical enhancement is approximated by the term 12(T,,o) in Eq. (10.1). However, while the actual thermal conductivity should become infinite at the critical point as it does for H 20,25 the thermal conductivity calculated from Eq. (10.1) remains finite at the critical point.
11. Computer-Program Verification To assist the user in computer-program verification, we
present a short table of values calculated for a number of thermophysical properties. The numerical values in Table 9 are given to six digits which is considered adequate for all practical purposes.
12. Acknowledgments We are indebted to our colleagues of the International
Association for the Properties of Steam, and in particular to P. G. Hill and A. Nagashima, who contributed much to the advancement of our knowledge of the properties and formulations for heavy water and steam. We acknowledge many stimulating discussions with P. G. Hill during the preparation of this paper.
This work was supported by the Office of Standard Reference Data at the National Bureau of Standards. The Com-
TABLE 9. Thermophysical property values calculated for selected values ofTandp
T p A P e" 1; X
0.50 0.0002 - 0.264519E + 1 0.440215E - 3 0.142768E + 2 0.197298E + 0 0.270065E + 2 0.50 3.1800 - O.217597E + 0 0.435497E + 1 O.414463E + 2 0; 124679E + 2 0.891182E + 3 0.75 0.0295 - 0.727350E + 1 0.870308E - 1 0.201586E + 2 O.295148E + 0 0.S52168E + 2 0.75 2.8300 - 0.429366E + 1 0.447530E + 1 0.334367E + 2 0.304176E + 1 0.869672E + 3 1.00 0.3000 -0.1516S0E+2 0.801404E + 0 0.308587E + 2 0.442482E + 0 0.143422E + 3 1.00 1.5500 - 0.12645SE + 2 O.109763E + 1 0.330103E + 2 0.110384E + 1 0.502847E + 3 1.20 0.4000 - 0.254738E + 2 O.14991OE + 1 O.236594E + 2 O.609454E + 0 0.160059E + 3 1.20 1.6100 - 0.21280SE + 2 0.456438E + 1 0.254800E + 2 0.127119E + 1 0.4 71748E + 3
J. Phys. Chern. Ref. Data, Vol. 13, No.2, 1984
THERMOPHYSICAL PROPERTIES OF FLUID 0 20 609
puter Science Center of the University of Maryland supplied computer time expended on this project.
13. References IJ. Kestin, J. V. Sengers, B. Kamgar-Parsi, and J. M. H. Levelt Sengers, J. Phys. Chem. Ref. Data 13,175 (1984).
2J. Kestin, J. V. Sengers, and R. C. Spencer, Mech. Eng. 105, 72 (1983). 3M. Uematsu and K. Watanabe, Survey oftbe Thermophysical Properties of Heavy Water (D20), Technical Report submitted to Working Group I oflAPS (Department ofMecbanical Engineering, Keio University, Y okohama, Japan, 1975).
4G. M.Murpby, in Isotopic and Cosmic Chemistry, edited by H. Craig, S. L. Miller and G. J. Wasserburg (North-Holland, Amsterdam, 1964), p. 7.
5F. G. Brickwedde, Phys. Today 35, 34 (1982). 6J. Kestin, Proceedings of the 8th Symposium on Thermophysical Properties, edited by J. V. Sengers (American Society of Mechanical Engineers, New York, 1982), Vol. I, p. 1.
7A. B. Lamb and R. E. Lee, J. Am. Chem. Soc. 35, 1666 (1913). 8G. N. Lewis and R. T. MacDonald, J. Am. Chern. Soc. 55, 3057 (1933). 9H. Craig, Science 133, 1833 (1961). lOp. L. Mohler, NBS Technical Note No. 51 (Natl. Bur. Stand., Wasbing
ton, D. c., 1960). lIG. S. KeD, J. Pbys. Chern. Ref. Data 6, 1109 (1977). 121. Kirshenbaum, Physical Properties and Analysis of Heavy Water
(McGraw-Hill, New York, 1951). 13Ya. Z. Kazavchinskii, P. M. Kessel'rnan, V. A. Kirillin, S. L. Rivkin, A.
E. Sheindlin, E. E. Shpil'rain, V. V. Sycbev, and D. L. Tirnrot, "Tyazhe-
laya Voda: Teplofizichiskie Svoistva (Gosenergoizdat, Moscow 1963). [English translation: "Heavy Water: Thermophysical Properties" (Israel Program for Scientific Translations, Jerusalem, 1971; available from the U. S. Department of Commerce, National Technical Information Service, Springfield, VA22151)].
14p. G. Hill, R. D. C. MacMillan, and V. Lee, J. Phys. Chern. Ref. Data 11,1 (1982).
15p. G. Hill, R. D. C. MacMillan, and V. Lee, Tables of Thermodynamic Properties of Heavy Water in S.l. Units (Atomic Energy of Canada, Mississauga, Ontario, 1981).
16B. Kamgar-Parsi, J. M. H. Levelt Sengers, and J. V. Sengers, J. Phys. Chem. Ref. Data 12,513 (1983).
17p. G. Hill and V. Lee, in Proceedings of the 8th Symposium on Thermophysical Properties, Vol. II, edited by J. V. Sengers (American Society of Mechanical Engineers, New York, 1982), p. 303.
18N. Matsunaga and A. Nagashima, J. Phys. Chem. Ref. Data 12, 933 (1983).
1~. R. Cohen and B. N. Taylor, J. Phys. Chem. Ref. Data 2, 663 (1973). 20J. Pupezin, G. Jakli, G. Jancso, and W. A. Van Hook, J. Phys. Chern. 76,
734 (1972). 21p. G. Hill and R. D. C. MacMi1lan, J. Phys. Chern. Ref. Data 9, 735
(1980). 22p. G. Hill, R. D. C. MacMillan, and V. Lee, J. Phys. Chem. Ref. Data 12,
1065 (1983). 23J. M. H. Levelt Sengers, B. Kamgar-Parsi, F. W. Balfour, and J. V.
Sengers. J. Phys. Chern. Ref. Data 12, 1 (1983). 24J. T. R. Watson, R. S. Basu, and J. V. Sengers, J. Phys. Chem. Ref. Data 9,
1255 (1980). 25J. V. Sengers, J. T. R. Watson, R. S. Basu, B. Kamgar-Parsi, and R. C.
Hendricks, J. Phys. Chern. Ref. Data (in press).
J. Phys. Chem. Ref. Data, Vol. 13, No.2, 1984